WANG Cong-Ling FU Jie MEI Hua YAN Da-WeiXU Yan

(College of Chemistry and Chemical Engineering,State Key Laboratory of Materials-oriented Chemical Engineering,Nanjing University of Technology,Nanjing 210009,China)

Hydrothermal Synthesis,Crystal Structure and Catalytic Properties of a Polyoxovanadate Organicamine

WANG Cong-Ling FU Jie MEI Hua＊YAN Da-WeiXU Yan＊

(College of Chemistry and Chemical Engineering,State Key Laboratory of Materials-oriented Chemical Engineering,Nanjing University of Technology,Nanjing210009,China)

A polyoxovanadate[NH3(CH2)4NH3][H2pip]2[V10O28]·6H2O(1,pip=piperazine)has been synthesized by hydrothermal method and characterized by elemental analysis,IR,TGA and single-crystal X-ray diffraction. Compound 1 crystallizes in the monoclinic system,space group P21/n,with cell parameters of a=1.22985(10)nm, b=1.07510(9)nm,c=1.49671(12)nm,β=93.9470(10)°,V=1.9743(3)nm3,Z=2.Crystallographic analysis reveals that it is constructed from anionic cluster[V10O28]6-,protonated 1,4-butanediamine and piperazine cations,as well as waters of crystallization.Organic cations and waters of crystallization further connect the anions into a threedimensional framework by water-anion hydrogen bonds O-H…O and cation-anion N-H…O interactions. CCDC:848090.

hydrothermal synthesis;polyoxovanadate;crystal structure

0 Introduction

During the past few years,polyoxovanadium have been extensively studied because of their diverse structure-and property-based functionalities in catalysis,electrical conductivity,selective adsorption,biological chemistry,magnetism and so on[1-4].During the last decade,an important advance in polyoxovanadium chemistry has been the rational design and assembly of V-O cluster anions and also V-O layers with an organic or bridging transition-metal complexed into extended three-dimensional (3D)frameworks[5].So far,a number of polyoxovanadium with 0D clusters,1Dchains,2D networks and 3D open frameworks have been reported[5-10].Decavanadate compounds[11],as a typical polyoxovanadium,are made of[V10O28]6-units that can be more or less protonated as[HnV10O28](6-n)-(n= 1～4)[12-13].The arrangement and specific orientation of the decavanadate units in their crystalline state are under active investigation in an attempt to determine the key factors for decavanadates self-assembly and design[14-20].Organic species providing short-range bonding interactions (hydrogen bonds,C-H/π)modify the principles guiding the crystal structure[12-20].In this work,we have successfully synthesized a polyoxovanadate[NH3(CH2)4NH3][H2pip]2[V10O28]·6H2O(1,pip= piperazine),constructed from anionic cluster[V10O28]6-, both protonated 1,4-butanediamine and piperazine cations,as well as waters of crystallization.

1 Experimental

1.1 Reagents and measurements

Allchemicalreagentswere purchased from commercialsources and ofreagentpurity.The elemental analysis (C,H,N)was performed on a Perkin-Elmer 2400 elemental analyzer.IR spectra determination was performed on a Nicolet 410 FTIR spectrometer in the range 400～4 000 cm-1(KBr pellet).The thermogravimetric analysis(TGA)was carried out on a Diamond thermalanalyzerundernitrogen atmosphere at a heating rate of 10℃·min-1.

1.2 Synthesis

AmixtureofV2O5(0.4032g,2.22mmol),piperazine (0.097 5 g,1.13 mmol),1,4-butanediamine(0.1029 g, 1.17 mmol),phosphoric acid(0.2 mL,2.93 mmol),and 10 mL distilled water was stirred for 0.5 h,then was neutralized to pH=7 with 6 mol·L-1NaOH.The mixture was sealed in a 20 mL Teflon-lined stainless steel reactor and heated to 160℃ for 7 d.After cooled to room temperature,theproductwaswashed with distilled water,filtered and dried in the air.Orange schistic-like crystals with a little unknown yellow powder were obtained(0.1863 g,yield 31.5%based on V).Elemental analysis:found(%):C,11.92;H,3.80;N, 6.39;Calcd.(%):C,10.81;H,3.75;N,6.31.

1.3 X-ray structure determination

The single crystals of compounds 1 was singled out under the microscope and glued at the tip of a thin glass fiber with epoxy glue in open air for data collection,and the crystallographic data were collected on a Bruker ApexⅡCCD with Mo Kα radiation(λ=0.071073 nm) at 296 K using ω-2θ scan method.The crystal structure was solved by direct method and refined on|F|2by fullmatrix least-squares methods using the SHELX97 program package[21].All of the non-hydrogen atoms were refined anisotropically.The hydrogen atoms of organoamine for complexes were placed in the calculation position.While the H atoms of water were located from the different Fourier maps.Crystallographic data and selected bond lengths are listed in Table 1 and 2, respectively.

CCDC:848090.

Table 1 Summary of crystallographic data for 1

Table 2 Selected bond lengths(nm)for 1

1.4 Catalysis experiment

According to our previous work[23-25],the oxidation of styrene was performed in 50 mL double necked round-bottomed flask fitted under the condition of water cooled condenser and magnetic stirrer.Styrene(0.75 mL,6.4 mmol)and compound 1 (50 mg)were respectively mixed in the flasks with 7.5 mL CH3CN solvent,and kept heating at 333 K.The hydrogen peroxide(30%)(2.2 mL,21.1 mmol)was added to the blended solution.The mixture was analyzed by a gas chromatograph (GC-6890,FID;30 m×0.32 mm capillary column)after 2 hours′s reaction.

2 Results and discussion

2.1 Crystal structure

Single-crystal X-ray analysis shows that compound 1 consists of[V10O28]6-anionic cluster,protonated 1,4-butanediamine and piperazine cations,and waters of crystallization(Fig.1).The ployoxoanion cluster is built up from five independent vanadium atoms,by means of an inversion center,an octahedrally packed cluster of 10 edge-shared VO6octahedra.The decavanadate anions exhibit a well-known cage-like structure,in which six vanadium atoms(V(1),V(3),V(5)and their crystallographic partners)are in the same plane,and four vanadium atoms(V(2),V(4)and their crystallographic partners)above and below the plane,with bond lengths in the range of 0.160 1(3)～0.169 9(3)nm for terminal oxygen and 0.180 5(3)～0.234 6(2)nm for bridging oxygen atoms.The O-V-O angles are in the range of 74.08(9)°～106.39(12)°and 154.33(1)°～174.83(12)°for cis-and trans-related bonds,respectively,consistent with [V10O28]6-clusters observed in other compounds[12-19].In compound 1,protonated 1,4-butanediamine and piperazine cations maintain the charge balance.

Fig.1 ORTEP view of the compound 1 structure showing the atom labeling scheme

It is worth of mentioning that there are a variety of O-H…O and N-H…O hydrogen bonds(Table 3).The out-projecting oxygen atoms of decavanadate clustersare strongly hydrogen-bonded to waters of crystallization and organic cations,with the O…O and O…N distances in the range of 0.269 4(4)～0.327 0(4)nm.Interestingly,decavanadate units are assembled into 1D chains by means of O(3w)-H…O(3)and O(3w)-H…O(13)hydrogenbonding interactions(Fig.2).In addition, adjacent 1D chains are linked by N(1)and N(2)of the piperazine cations using hydrogen bonds to generate a 2D soft layer,as shown in Fig.3.Then,the hydrogen bonds connect 1,4-butanediamine cations between the adjacent soft layers to make a soft 3D supermolecular open framework,as depicted in Fig.4.To best of our

knowledge,decavanadates including two typesof protonated organic amine cations are very rare.The assignment of oxidation states for V of 1 are based on bond valence sum calculations[22],which give average oxidation of+5 for V.The calculated value is in agreement with the formula of 1.The synthesis of compound 1 demonstrates that the presence of two types organic species providing hydrogen bonding interactions can modify new vanadates.

Table 3 Distances and angles of the hydrogen bond interactions in 1

Fig.2 Adjacent decavanadate are connected by hydrogen bonding from waters of crystallization to make 1D chains

Fig.3 Adjacent 1D chains are connected by hydrogen bonding from piperazine cations to make a soft layer

Fig.4 1,4-butanediamine cations filled by hydrogen bonds between the adjacent polyanion layers to make a 3D framework

2.2 Infrared spectra

The IR spectrum of 1 shows two strong bands,the one in 951 cm-1is due to ν(V=O),while the other at 561～830 cm-1are attributed to ν(O-V-O)and ν(V-Ob).Typically sharp peaks for 1,4-diaminobutane and piperazine are at the region of 1 383～1 616 cm-1.In addition,the broad bands at 3 018～3 444 cm-1are due to ν(O-H)and ν(N-H).

2.3 TG analysis

As shown in Fig.5,total weight loss is 28.90%in the range of 38～550℃,which is in agreement with the calculated value(31.73%).Weight loss of 7.90%from 72 to 205℃ is assigned to the removal of the crystal water molecules(calculated value:8.11%).Weight loss of 11.70%from 205 to 370℃ is attributable to the decomposition of piperazine (calculated value: 13.24%).Weight loss 9.20%from 370 to 550℃is due to the decomposition of 1,4-diaminobutane(calculated value:6.77%).

Fig.5 Thermogravimetric analysis of 1

2.4 Catalytic property

Although the 5%conversion of styrene is poor, selectivity of benzaldehyde,benzoic acid and epoxide were 100%,0%and 0%,respectively.The catalytic property results show that compound 1 has low conversion and high selectivity for benzaldehyde.

[1]Müller A,Peters F,Pope M T,et al.Chem.Rev.,1998,98:239-272

[2]Gouzerh P,Proust A.Chem.Rev.,1998,98:77-111

[3]Dolbecq A,Dumas E,Mayer C R,et al.Chem.Rev.,2010, 110:6009-6048

[4]Long D L,Tsunashima R,Cronin L.Angew.Chem.,Int.Ed., 2010,49:1736-1758

[5]Xu Y,Zhou G P,Zhu D R.Inorg.Chem.,2008,47:567-571

[6]Zhou G P,Xu Y,Guo C Y,et al.J.Cluster Sci.,2007,18:388-395

[7]Khan M I,Yohannes E,Doedens R J.Angew.Chem.,Int.Ed., 1999,38:1292-1294

[8]Xu Y,Nie L B,Zhu D R,et al.Cryst.Growth Des.,2007,7: 925-929

[9]Rarig R S J,Zubieta J.Dalton Trans.,2003,9:1861-1868

[10]Zhang Z B,Xu Y,Zheng L,et al.Z.Anorg.Allg.Chem., 2010,636:1576-1579

[11]Evans H.Inorg.Chem.,1966,5:967-977

[12]Jouffret L,Rivenet M,Abraham F.Inorg.Chem.Commun., 2010,13:5-9

[13]Kojima T,Antonio M R,Ozeki T.J.Am.Chem.Soc.,2011, 133:7248-7251

[14]Klitincová L,Rakovsk E,Schwendt P,et al.Inorg.Chem. Commun.,2010,13:1275-1277

[15]Klitincová L,Rakovsk E,Schwendt P.Inorg.Chem.Commun., 2008,11:1140-1142

[16]Gil-García R,Zichner R,Díez-Gómez V.Eur.J.Inorg.Chem., 2010:4513-4525

[17]Zhang X M,Chen X M.Inorg.Chem.Commun.,2003,6:206-209

[18]Zheng L,Wang Y S,Wang X Q,et al.Inorg.Chem.,2001,40: 1380-1385

[19]Duraisamy T,Ojha N,Ramanan A,et al.Chem.Mater.,1999, 11:2339-2349

[20]Khan M I,Chen Q,Goshorn D P.J.Am.Chem.Soc.,1992, 114:3341-3346

[21]Sheldrick G M.SHELXTL Version 5.10,Bruker AXS Inc. Madsion,Wisconsion,USA,1997.

[22]Brown I D.Chem.Rev.,2009,109:6858-6919

[23]Chen Q,Cui Y,Sun Q,et al.Z.Anorg.Allg.Chem.,2009, 635:2302-2308

[24]Mei H,Yan D W,Chen Q.Inorg.Chim.Acta,2010,363:2265 -2268

[25]SUN Yue-Xia(孫月霞),ZHANG Zhi-Bin(張志斌),SUN Qi(孫琪),et al.Chem.J.Chin.Univ.(Gaodeng Xuexiao Huaxue Xuebao),2011,27:556-560

一種多釩氧酸有機(jī)銨鹽的水熱合成、晶體結(jié)構(gòu)及催化性質(zhì)研究

王從嶺 付 潔 梅 華＊顏大偉 許 巖＊

(南京工業(yè)大學(xué)化學(xué)化工學(xué)院，材料化學(xué)工程國家重點(diǎn)實(shí)驗(yàn)室，南京 210009)

本文采用水熱技術(shù)合成了一種多釩氧酸鹽[NH3(CH2)4NH3][H2pip]2[V10O28]·6H2O(1，pip=哌嗪)，并且通過元素分析、紅外、熱重、單晶X-射線衍射對化合物1進(jìn)行了表征?；衔?為單斜晶系,空間群為P21/n,晶胞參數(shù)為a=1.22985(10)nm,b=1.07510(9) nm，c=1.49671(12)nm，β=93.9470(10)°，V=1.9743(3)nm3，Z=2。晶體結(jié)構(gòu)分析表明，化合物1是由[V10O28]6-陰離子簇、質(zhì)子化的1，4-丁二胺和哌嗪陽離子以及結(jié)晶水構(gòu)成。有機(jī)陽離子和結(jié)晶水通過O-H…O和N-H…O氫鍵相互作用將陰離子連接形成三維結(jié)構(gòu)。

水熱合成；多釩氧酸鹽；晶體結(jié)構(gòu)

O614.51+1

A

1001-4861(2012)01-0176-05

2011-07-20。收修改稿日期：2011-09-13。

國家自然科學(xué)基金(No.20971068)資助項(xiàng)目。

＊通訊聯(lián)系人。E-mail：yanxu@njut.edu.cn